Acetamide as a Solvent

By O. F. Stafford. Assuming a measure of validity for the doctrine that a substance dis- solves other substances of its own kind, a most interesting c...
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Oct., 1933

ACETAMIDEAS

[CONTRIBUTION FROM THE CHEMISrRY

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SOLVENT

LABORATORY O F THE

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Acetamide as a Solvent BY 0. F. STAFFORD

Assuming a measure of validity for the doctrine that a substance dissolves other substances of its own kind, a most interesting case should be presented by acetamide as a solvent. This substance melts a t about 80" to form a fairly mobile liquid. The fact that it contains a methyl group should give it solvent powers for hydrocarbons; its carbonyl group relates it to ketones, esters and acids; its tautomeric hydroxyl grcup gives it kinship to water and the alcohols; its amino group brings it into line with ammonia and its derivatives, while the ease with which it yield: nitrile suggests a relationship to cyanogen compounds. I n the field of inorganic chemistry the above considerations are supplemented by the fact that acetamide outranks all but a half dozen substances in the magnitude of its dielectric constant (59.2). To test these assumptions the approximate solubilities of some 400 organic compounds and about half that number of inorganic c3mpounds have been ascertained. The procedure, in general, was merely :o add the substance to fused acetamide (at about 100') and to note w'iether much or little would dissolve. Where in any instance the solu1)ility thus appeared to be slight, the influence of higher temperatures w 1s investigated. Sparingly soluble inorganic compounds were not only testcbd directly, but in most cases were precipitated by suitable double substitiition reactions. I t is interesting to note that these precipitation reactions occur with the same readiness as in water or ammonia as solvent. The general results may be summarized by saying that of the 400 organic substances the only one showing no indications of solubility was cellulose. Asparagine, barbituric acid, oxamifle and uric acid are sparingly soluble a t low temperatures (i. e., below 100"). I t is significant that these same substances are but slightly soluble in wate- and are rated as insoluble in alcohol and ether. The solubilities of the inorganic compounds are strikingly analogous to those in water. Exceptions are presented by potassium perchlorate, the halides of mercury ar.d lead, and the phosphate and oxide of mercury, all of which are more soluhle in acetamide than in water. More specifically, it was found that among organic compounds sixtyfive ammonia-nitrogen derivatives (except uric acid), seventeen carbohydrates (excepting cellulose but including starch), sixty-eight dyestuffs, forty-four alcohols, eleven nitro and nitroso compounds and a number of miscellaneous nitrogen derivatives, all dissolve readily. Of the twenty hydrocarbons tested, anthracene, phenanthrene and triphenylmethane are quite soluble The others are soluble a t higher temperatures, but

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separate out to form two-phase systems a t lower temperatures (80 to 180'). Forty-five acids tested are all soluble, but those with very long hydrocarbon chains are less soluble than the others. Some twenty oxygen compounds were tested, in this class the ethers appearing to be somewhat less soluble than the others. Among inorganic compounds bismuth nitrate gives a white insoluble compound similar to that formed by hydrolysis or ammonolysis. MerCUTOUS nitrate undergoes some transformation in contact with the solvent. A similar action appears to take place with mercurous halides. Chromates are slowly reduced in acetamide solutions, although even the solution of chromium trioxide (which in color exactly resembles solutions of chromates) is stable for quite a while. The brown silver carbonate precipitate is presumably in the form of silver oxide, as in the case of precipitation from water. The close analogy between acetamide and water as solvent is proved not only by the close correspondence which is shown by solubilities of inorganic compounds in these two substances but also by the chemical behaviors of dissolved substances. Mention has already been made of the fact that double substitution reactions occur with the same readiness in acetamide solution as in water solution. In such cases the precipitates in acetamide are even similar in appearance to those formed in water, colored sulfides, for example, appearing precisely as when precipitated from water. A search of the literature reveals that conductivity curves for a considerable number of salts in acetamide solution have been determined and that these curves resemble those obtained in water solutions. Furthermore, it has been shown that electrodeposition occurs readily in acetamide solutions with metals not more active than zinc. Numerous instances are described in which acetamide seems to function analogously to water of crystallization. I t follows, therefore, that' the expectations enumerated in the opening paragraph of this article are surprisingly substantiated by experiment. Seemingly acetamide has a wider range of solvent powers than any other substance which has been reported. EUGENE, OREGON

RECEIVED MAY29, 1933 PUBLISHED OCTOBER6, 1933